Patent application number | Description | Published |
20080197399 | Nanotip capacitor - A nanotip capacitor and associated fabrication method are provided. The method provides a bottom electrode and grows electrically conductive nanotips overlying the bottom electrode. An electrically insulating dielectric is deposited overlying the nanotips, and an electrically conductive top electrode is deposited overlying dielectric-covered nanotips. Typically, the dielectric is deposited by forming a thin layer of dielectric overlying the nanotips using an atomic layer deposition (ALD) process. In one aspect, the electrically insulating dielectric covering the nanotips forms a three-dimensional interface of dielectric-covered nanotips. Then, the electrically conductive top electrode overlying the dielectric-covered nanotips forms a three-dimensional top electrode interface, matching the first three-dimensional interface of the dielectric-covered nanotips. | 08-21-2008 |
20080277701 | High energy implant photodiode stack - An array of fully isolated multi-junction complimentary metal-oxide-semiconductor (CMOS) filterless color imager cells is provided, with a corresponding fabrication process. The color imager cell array is formed from a bulk silicon (Si) substrate without an overlying epitaxial Si layer. A plurality of color imager cells are formed in the bulk Si substrate, where each color imager cell includes a photodiode set and a U-shaped well liner. The photodiode set includes first, second, and third photodiode formed as a stacked multifunction structure, while the U-shaped well liner fully isolates the photodiode set from adjacent photodiode sets in the array. The U-shaped well liner includes a physically interfacing doped well liner bottom and first wall. The well liner bottom is interposed between the substrate and the photodiode set, and the first wall physically interfaces each doped layer of each photodiode in the photodiode set. | 11-13-2008 |
20080277746 | Nanowire sensor with self-aligned electrode support - A nanowire sensor with a self-aligned top electrode support insulator, and associated fabrication process are provided. The method begins with a doped silicon-containing substrate. A growth-promotion metal is deposited overlying the substrate. A silicon nitride electrode support is formed overlying the growth-promotion metal. Nanowires are grown from exposed regions of the growth-promotion metal and an insulator is deposited over the nanowires. A top insulator layer is removed to expose tips of the nanowires, and a top electrode metal is deposited overlying the nanowire tips and silicon nitride electrode support. Next, a stack etch is selectively performed, etching down to the level of the growth-promotion metal. A top electrode island is left that is centered on the silicon nitride electrode support and connected to the growth-promotion metal via the nanowires. Then, the sensor is dipped in a buffered hydrofluoric (BHF) solution, to remove any remaining insulator and to expose the nanowires. | 11-13-2008 |
20080280426 | Gallium nitride-on-silicon interface - A method is provided for forming a matching thermal expansion interface between silicon (Si) and gallium nitride (GaN) films. The method provides a (111) Si substrate and forms a first aluminum (Al)-containing film in compression overlying the Si substrate. Nano-column holes are formed in the first Al-containing film, which exposes regions of the underlying Si substrate. A layer of GaN layer is selectively grown from the exposed regions, covering the first Al-containing film. The GaN is grown using a lateral nanoheteroepitaxy overgrowth (LNEO) process. The above-mentioned processes are reiterated, forming a second Al-containing film in compression, forming nano-column holes in the second Al-containing film, and selectively growing a second GaN layer. Film materials such as Al | 11-13-2008 |
20080290408 | Thin silicon-on-insulator double-diffused metal oxide semiconductor transistor - A method is provided for fabricating a silicon (Si)-on-insulator (SOI) double-diffused metal oxide semiconductor transistor (DMOST) with a stepped channel thickness. The method provides a SOI substrate with a Si top layer having a surface. A thinned area of the Si top layer is formed, and a source region is formed in the thinned Si top layer area. The drain region is formed in an un-thinned area of the Si top layer. The channel has a first thickness adjacent the source region with first-type dopant, and a second thickness, greater than the first thickness, adjacent the drain region. The channel also has a sloped thickness between the first and second thicknesses. The second and sloped thicknesses have a second-type dopant, opposite of the first-type dopant. A stepped gate overlies the channel. | 11-27-2008 |
20080290431 | Nanorod sensor with single-plane electrodes - A nanorod sensor with a single plane of horizontally-aligned electrodes and an associated fabrication method are provided. The method provides a substrate and forms an intermediate electrode overlying a center region of the substrate. The intermediate electrode is a patterned bottom noble metal/Pt/Ti multilayered stack. TiO | 11-27-2008 |
20080296616 | Gallium nitride-on-silicon nanoscale patterned interface - A method is provided for forming a matching thermal expansion interface between silicon (Si) and gallium nitride (GaN) films. The method provides a (111) Si substrate that is heated to a temperature in a range of about 300 to 800° C., and a first film is formed in compression overlying the Si substrate. The first film material may be InP, SiGe, GaP, GaAs, AlN, AlGaN, an AlN/graded AlGaN (Al | 12-04-2008 |
20080296625 | Gallium nitride-on-silicon multilayered interface - A multilayer thermal expansion interface between silicon (Si) and gallium nitride (GaN) films is provided, along with an associated fabrication method. The method provides a (111) Si substrate and forms a first layer of a first film overlying the substrate. The Si substrate is heated to a temperature in the range of about 300 to 800° C., and the first layer of a second film is formed in compression overlying the first layer of the first film. Using a lateral nanoheteroepitaxy overgrowth (LNEO) process, a first GaN layer is grown overlying the first layer of second film. Then, the above-mentioned processes are repeated: forming a second layer of first film; heating the substrate to a temperature in the range of about 300 to 800° C.; forming a second layer of second film in compression; and, growing a second GaN layer using the LNEO process. | 12-04-2008 |
20080299381 | IrOx nanowire neural sensor - An iridium oxide (IrOx) nanowire neural sensor array and associated fabrication method are provided. The method provides a substrate with a conductive layer overlying the substrate, and a dielectric layer overlying the conductive layer. The substrate can be a material such as Si, SiO | 12-04-2008 |
20080303072 | CMOS Active Pixel Sensor - A CMOS active pixel sensor includes a silicon-on-insulator substrate having a silicon substrate with an insulator layer formed thereon and a top silicon layer formed on the insulator layer. A stacked pixel sensor cell includes a bottom photodiode fabricated on the silicon substrate, for sensing light of a longest wavelength; a middle photodiode fabricated on the silicon substrate, for sensing light of a medium wavelength, which is stacked above the bottom photodiode; and a top photodiode fabricated on the top silicon layer, for sensing light of a shorter wavelength, which is stacked above the middle and bottom photodiodes. Pixel transistor sets are fabricated on the top silicon layer and are associated with each pixel sensor cell by electrical connections which extend between each of the photodiodes and respective pixel transistor(s). CMOS control circuitry is fabricated adjacent to an array of active pixel sensor cells and electrically connected thereto. | 12-11-2008 |
20080315255 | Thermal Expansion Transition Buffer Layer for Gallium Nitride on Silicon - A method is provided for forming a matching thermal expansion interface between silicon (Si) and gallium nitride (GaN) films. The method provides a (111) Si substrate with a first thermal expansion coefficient (TEC), and forms a silicon-germanium (SiGe) film overlying the Si substrate. A buffer layer is deposited overlying the SiGe film. The buffer layer may be aluminum nitride (AlN) or aluminum-gallium nitride (AlGaN). A GaN film is deposited overlying the buffer layer having a second TEC, greater than the first TEC. The SiGe film has a third TEC, with a value in between the first and second TECs. In one aspect, a graded SiGe film may be formed having a Ge content ratio in a range of about 0% to 50%, where the Ge content increases with the graded SiGe film thickness. | 12-25-2008 |
20080315304 | Thin silicon-on-insulator high voltage auxiliary gated transistor - A silicon (Si)-on-insulator (SOI) high voltage transistor is provided with an associated fabrication process. The method provides a SOI substrate with a Si top layer. A control channel and an adjacent auxiliary channel are formed in the Si top layer. A control gate overlies the control channel and an auxiliary gate overlies the auxiliary channel. A source region is formed adjacent the control channel, and a lightly doped drain (LDD) region is interposed between the auxiliary channel and the drain. An interior drain region is interposed between the control and auxiliary channels. Typically, the Si top layer has a thickness in the range of 20 to 1000 nm. In one aspect, the Si top layer in the source, control channel, interior drain, and auxiliary channel regions is thinned to a thickness in the range of 5 to 200 nm, and raised source, drain, LDD, and interior drain regions are formed. | 12-25-2008 |
20090008647 | Gallium nitride-on-silicon interface using multiple aluminum compound buffer layers - A thermal expansion interface between silicon (Si) and gallium nitride (GaN) films using multiple buffer layers of aluminum compounds has been provided, along with an associated fabrication method. The method provides a (111) Si substrate and deposits a first layer of AlN overlying the substrate by heating the substrate to a relatively high temperature of 1000 to 1200° C. A second layer of AlN is deposited overlying the first layer of AlN at a lower temperature of 500 to 800° C. A third layer of AlN is deposited overlying the second layer of AlN by heating the substrate to the higher temperature range. Then, a grading Al | 01-08-2009 |
20090011536 | OPTICAL DEVICE WITH IROX NANOSTRUTURE ELECTRODE NEURAL INTERFACE - An optical device with an iridium oxide (IrOx) electrode neural interface, and a corresponding fabrication method are provided. The method provides a substrate and forms a first conductive electrode overlying the substrate. A photovoltaic device having a first electrical interface is connected to the first electrode. A second electrical interface of the photovoltaic device is connected to a second conductive electrode formed overlying the photovoltaic device. An array of neural interface single-crystal IrOx nanostructures are formed overlying the second electrode, where x≦4. The IrOx nanostructures can be partially coated with an electrical insulator, such as SiO | 01-08-2009 |
20090017197 | IrOx nanowire protein sensor - An iridium oxide (IrOx) nanowire protein sensor and associated fabrication method are presented. The method provides a substrate and forms overlying working and counter electrodes. A dielectric layer is deposited over the working and counter electrodes and contact holes are formed in the dielectric layer, exposing regions of the working and counter electrodes. IrOx nanowires (where 0≦X≦2) are grown from exposed regions of the working electrode. In one aspect, the IrOx nanowires are additionally grown on the dielectric, and subsequently etched from the dielectric. In another aspect, IrOx nanowires are grown from exposed regions of the counter electrode. | 01-15-2009 |
20090024182 | IrOx Nanostructure Electrode Neural Interface Optical Device - An optical device with an iridium oxide (IrOx) electrode neural interface, and a corresponding fabrication method are provided. The method provides a substrate and forms a first conductive electrode overlying the substrate. A photovoltaic device having a first electrical interface is connected to the first electrode. A second electrical interface of the photovoltaic device is connected to a second conductive electrode formed overlying the photovoltaic device. An array of neural interface single-crystal IrOx nanostructures are formed overlying the second electrode, where x≦4. The IrOx nanostructures can be partially coated with an electrical insulator, such as SiO | 01-22-2009 |
20090032817 | Back-To-Back Metal/Semiconductor/Metal (MSM) Schottky Diode - A method is provided for forming a metal/semiconductor/metal (MSM) back-to-back Schottky diode from a silicon (Si) semiconductor. The method deposits a Si semiconductor layer between a bottom electrode and a top electrode, and forms a MSM diode having a threshold voltage, breakdown voltage, and on/off current ratio. The method is able to modify the threshold voltage, breakdown voltage, and on/off current ratio of the MSM diode in response to controlling the Si semiconductor layer thickness. Generally, both the threshold and breakdown voltage are increased in response to increasing the Si thickness. With respect to the on/off current ratio, there is an optimal thickness. The method is able to form an amorphous Si (a-Si) and polycrystalline Si (polySi) semiconductor layer using either chemical vapor deposition (CVD) or DC sputtering. The Si semiconductor can be doped with a Group V donor material, which decreases the threshold voltage and increases the breakdown voltage. | 02-05-2009 |
20090057758 | Thin silicon-on-insulator high voltage transistor with body ground - A silicon (Si)-on-insulator (SOI) high voltage transistor with a body ground is provided with an associated fabrication process. The method provides a SOI substrate with a buried oxide (BOX) layer and a Si top layer having a first thickness and a second thickness, greater than the first thickness. A body ground is formed in the second thickness of Si top layer overlying the BOX layer. A control channel is formed in the first thickness of the Si top layer. A control gate is formed overlying the control channel. An auxiliary channel is formed in the second thickness of Si top layer partially overlying the body ground and extending into the first thickness of the Si top layer. An auxiliary gate is formed overlying the auxiliary channel. A pn junction is formed in the second thickness of Si top layer between the auxiliary channel and the body ground. | 03-05-2009 |
20090173933 | Thermal Sensor with a Silicon/Germanium Superlattice Structure - A silicon/germanium (SiGe) superlattice thermal sensor is provided with a corresponding fabrication method. The method forms an active CMOS device in a first Si substrate, and a SiGe superlattice structure on a second Si-on-insulator (SOI) substrate. The first substrate is bonded to the second substrate, forming a bonded substrate. An electrical connection is formed between the SiGe superlattice structure and the CMOS device, and a cavity is formed between the SiGe superlattice structure and the bonded substrate. | 07-09-2009 |
20090194799 | Dual-pixel Full Color CMOS Imager - A dual-pixel full color complementary metal oxide semiconductor (CMOS) imager is provided, along with an associated fabrication process. Two stand-alone pixels are used for three-color detection. The first pixel is a single photodiode, and the second pixel has two photodiodes built in a stacked structure. The two photodiode stack includes an n doped substrate, a bottom photodiode, and a top photodiode. The bottom photodiode has a bottom p doped layer overlying the substrate and a bottom n doped layer cathode overlying the bottom p doped layer. The top photodiode has a top p doped layer overlying the bottom n doped layer and a top n doped layer cathode overlying the top p doped layer. The single photodiode includes the n doped substrate, a p doped layer overlying the substrate, and an n doped layer cathode overlying the p doped layer. | 08-06-2009 |
20090219410 | CMOS Imager Flush Reset - A complementary metal oxide semiconductor (CMOS) imager flush reset circuit is provided. The flush reset circuit has an interface to receive first (e.g., V | 09-03-2009 |
20100090110 | Ge Imager for Short Wavelength Infrared - A germanium (Ge) short wavelength infrared (SWIR) imager and associated fabrication process are provided. The imager comprises a silicon (Si) substrate with doped wells. An array of pin diodes is formed in a relaxed Ge-containing film overlying the Si substrate, each pin diode having a flip-chip interface. There is a Ge/Si interface, and a doped Ge-containing buffer interposed between the Ge-containing film and the Ge/Si interface. An array of Si CMOS readout circuits is bonded to the flip-chip interfaces. Each readout circuit has a zero volt diode bias interface. | 04-15-2010 |